{"id":601,"date":"2021-04-08T17:26:10","date_gmt":"2021-04-08T21:26:10","guid":{"rendered":"https:\/\/opentextbc.ca\/autocad3d\/chapter\/surface-modeling-part-2\/"},"modified":"2021-11-04T11:38:10","modified_gmt":"2021-11-04T15:38:10","slug":"surface-modeling-part-2","status":"publish","type":"chapter","link":"https:\/\/opentextbc.ca\/autocad3d\/chapter\/surface-modeling-part-2\/","title":{"raw":"Module 13: Surface Modeling – Part 2","rendered":"Module 13: Surface Modeling – Part 2"},"content":{"raw":"
\n

Learning Outcomes<\/p>\n\n<\/header>\n

\n\nWhen you have completed this module, you will be able to:\n
    \n \t
  1. Describe geometry defined meshes including rule surfaces, revolved surfaces, and tabulated surfaces.<\/li>\n \t
  2. Apply the RULESURF, REVSURF, and TABSURF commands to apply mesh surfaces to 3D models.<\/li>\n<\/ol>\n<\/div>\n<\/div>\n

    Geometry Defined Surface Meshes<\/h1>\nGeometrically defined surface meshes <\/em><\/span>use existing geometry that must be created before the surfaces. In almost all cases, the wireframe of the model is used as the existing geometry. There are four geometrically defined surface meshes that can be created in AutoCAD. They are the ruled surface, revolved surface, tabulated surface, and edge surface. The commands to create these meshes are RULESURF, REVSURF, TABSURF, and EDGESURF. The EDGESURF command is taught in Module 15.\n\nTo create a geometry defined surface mesh, start with the wireframe geometry and ensure that it is on its own layer. Surface the wireframe model on all sides, making sure that all exposed sides have a surface covering them. Think of the model as an object that must be made water tight.\n\nEven the inside of a hole going through the model must have a surface applied on it. Place the surface meshes on their own layer. When the surfaced model is complete, freeze the layer containing the wireframe or the geometry leaving only the layer with the surface mesh displayed.\n

    Ruled Surface<\/h2>\nA ruled surface<\/em><\/span>, inserted with the RULESURF command, is the most commonly used method to surface a model. To place a ruled surface, simply select two lines, a line and an arc, two arcs, or two circles to place the surface between. See Figure 13-1.\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"394\"]\"\" Figure 13-1
    Ruled Surface[\/caption]\n

    Revolved Surface<\/h2>\nA revolved surface<\/em><\/span>, inserted with the REVSURF command, is a surface created by revolving a profile around an axis. The profile can be a line, arc, circle, or an open or closed 2D polyline or 3D polyline. See Figure 13-2. The axis must be a line or an open 2D or 3D polyline. If a polyline is used as the axis, the REVSURF command will simply use a straight line between the start point and end point of the polyline.\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"583\"]\"\" Figure 13-2
    Revolved Surface[\/caption]\n

    Tabulated Surface<\/h2>\nA tabulated surface<\/span>, <\/em>inserted with the TABSURF command, is a surface created by projecting a profile along a path. The profile defines the surface of the mesh as it follows the path. See Figure 13-3. The profile can be a line, arc, circle, ellipse, or an open or closed 2D or 3D polyline. The path can be a line or a polyline. If a polyline is used as the axis, the TABSURF command will simply use a straight line between the start point and end point of the polyline. The surface is drawn starting at the point on the profile closest to the point selected in the command.\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"526\"]\"\" Figure 13-3
    Tabulated Surface[\/caption]\n

    Setting the Mesh Density<\/h2>\nThe mesh density<\/span> <\/em>represented by the lines, circles, or arcs that make the rows and columns of the surface mesh are controlled with the system variables SURFTAB1 and SURFTAB2. On flat surfaces, the density of the mesh is not that important but with curved or irregular shaped surfaces, the density is very important since the higher the setting, the more segments are used when creating circles and arcs. If the mesh is not dense enough, small gaps will be left where a curved surface meets a flat surface. See Figure 13-4.\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"600\"]\"\" Figure 13-4
    SURFTAB Settings[\/caption]\n\n
    \n

    AutoCAD Command: RULESURF<\/p>\n\n<\/header>\n

    \n\nThe RULESURF command is used to create a rule surface between two existing edges.\n\nShortcut: none\n\nSURFTAB1 = YES\n\nSURFTAB2 = No Effect\n\n[caption id=\"attachment_544\" align=\"aligncenter\" width=\"508\"]\"\" Draw Pull-down[\/caption]\n\n[caption id=\"attachment_544\" align=\"aligncenter\" width=\"255\"]\"\" Mesh Ribbon[\/caption]\n\n<\/div>\n<\/div>\n

    WORK ALONG: Inserting Ruled Surfaces<\/h1>\n

    Step 1<\/h2>\nUsing the NEW command, start a new drawing using template: 3D Layout Metric<\/span>.\n

    Step 2<\/h2>\nSave and name the drawing: AutoCAD 3D Workalong 13-1<\/span>.\n

    Step 3<\/h2>\nSet the current layer to: Model<\/span> and the current visual style to 2D Wireframe.\n

    Step 4<\/h2>\nDraw a wireframe model of the multiview drawing. (Figure Step 4A and 4B)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"222\"]\"\" Figure Step 4A
    Wireframe Model[\/caption]\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"500\"]\"\" Figure Step 4B
    Dimensioned Multiview Drawing[\/caption]\n

    Step 5<\/h2>\nSet the system variable SURFTAB1 to 24 as shown below: Command: SURFTAB1<\/strong>\n\nEnter new value for SURFTAB1 <8>: 24<\/strong>\n\nCommand:\n
    AUTHOR'S COMMENTS:<\/strong> Setting SURFTAB1 to 24 sets the mesh density to 24 for the ruled surfaced inserted.<\/div>\n

    Step 6<\/h2>\nOn layer: Construction<\/span>, draw a line along the top edge of each side of the model. (Figure Step 6)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"249\"]\"\" Figure Step 6[\/caption]\n\n
    AUTHOR'S COMMENTS:<\/strong> On some models, construction lines must be drawn on the wireframe to make it easier to insert surfaces.<\/div>\n

    Step 7<\/h2>\nSet layer: Surface 1<\/span> as the current layer. Enter the RULESURF command, as shown below, to insert a ruled surface. (Figure Step 7A and 7B)\n\nCommand: RULESURF<\/strong>\n\nCurrent wire frame density: SURFTAB1=24\n\nSelect first defining curve: P1<\/strong>\n\nSelect second defining curve: P2<\/strong>\n\nCommand:\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"303\"]\"\" Figure Step 7A[\/caption]\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"303\"]\"\" Figure Step 7B[\/caption]\n

    Step 8<\/h2>\nRepeat the RULESURF command and insert surfaces all around the edge of the model. (Figure Step 8)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"320\"]\"\" Figure Step 8[\/caption]\n

    Step 9<\/h2>\nTurn layer: Surface Off<\/span> off and lock layers: Model<\/span> and Construction<\/span>. Select all of the surfaces inserted in Steps 7 and 8 and change their layer to: Surface Off<\/span>. (Figure Step 9)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"425\"]\"\" Figure Step 9[\/caption]\n\n
    AUTHOR'S COMMENTS: <\/strong>I use a little trick in Step 9 to help you when surfacing the model. I temporarily change the layers of newly created surfaces to a layer that is turned off. That way, the surfaces do not display and get in the way while you are inserted additional surfaces on the model. When all of the surfaces are inserted to complete the model, turn layer Surface Off on and change the layer of all surfaces back to layer Surface 1. The reason I locked layers Model and Construction is to make is easier to select only the surfaces using windows when changing their layer property.<\/div>\n

    Step 10<\/h2>\nUsing what was just taught, insert ruled surfaces around the top of the object and inside of the hole as shown in the figure. (Figure Step 10).\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"253\"]\"\" Figure Step 10[\/caption]\n

    Step 11<\/h2>\nChange the layer of the surfaces inserted in Step 10 to layer: Surface Off<\/span>.\n

    Step 12<\/h2>\nOn layer: Construction<\/span>, draw the construction lines on the top surface as shown in the figure. Ensure to snap to the endpoints of the lines and arcs. (Figure Step 12)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"300\"]\"\" Figure Step 12[\/caption]\n\n
    MUST KNOW:<\/strong> When using the RULESURF command, ensure that you select the objects closest to matching ends. If opposite ends are selected, the mesh will twist as shown in the figure.\"\"<\/div>\n

    Step 13<\/h2>\nOn layer: Surface 1<\/span>, use the RULESURF command to insert the surfaces as shown in the figure. Change the surfaces the layer: Surface off<\/span>. (Figure Step 13)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"314\"]\"\" Figure Step 13[\/caption]\n

    Step 14<\/h2>\nOn layer: Surface 1<\/span>, use the RULESURF command to draw surfaces as shown in the figure. Change the layer of the surfaces to layer: Surface off<\/span>. (Figure Step 14)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"314\"]\"\" Figure Step 14[\/caption]\n

    Step 15<\/h2>\nOn layer: Construction<\/span>, draw a 180 degree arc on the top half of the circle. Ensure that you snap to the quads of the circle. To do that, ensure to locate the UCS on the same plane as the circle. (Figure Step 15)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"300\"]\"\" Figure Step 15[\/caption]\n

    Step 16<\/h2>\nOn layer: Surface 1<\/span>, insert a ruled surface between the arcs. (Figure Step 16)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"300\"]\"\" Figure Step 16[\/caption]\n\n
    AUTHOR'S COMMENTS:<\/strong> Ensure that you select the arc instead of the circle under it. Sometimes, this can be tricky.<\/div>\n

    Step 17<\/h2>\nChange the layer of the surface that you just drew to layer: Surface Off<\/span>.\n

    Step 18<\/h2>\nDraw two construction lines and a construction arc on the bottom half of the circle. (Figure Step 18)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"300\"]\"\" Figure Step 18[\/caption]\n

    Step 19<\/h2>\nOn layer: Surface 1<\/span>, insert a ruled surface. (Figure Step 19)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"303\"]\"\" Figure Step 19[\/caption]\n

    Step 20<\/h2>\nOn layer: Surface 1<\/span>, insert the ruled surfaces as shown in the figure. (Figure Step 20)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"300\"]\"\" Figure Step 20[\/caption]\n

    Step 21<\/h2>\nChange the layer of the existing surfaces to layer: Surface 1<\/span> until your model matches the figure. (Figure Step 21)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"364\"]\"\" Figure Step 21[\/caption]\n

    Step 22<\/h2>\nCopy the surfaces from the front side of the model to back side. (Figure Step 22)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"319\"]\"\" Figure Step 22[\/caption]\n\n
    AUTHOR'S COMMENTS:<\/strong> To help you surface a model faster, you can copy surfaces from one side of a model to another, if they are identical.<\/div>\n

    Step 23<\/h2>\nUsing what was just taught, complete surfacing the model. Ensure to surface the bottom of the model. When complete, change all the surfaces from layers: Surface off<\/span> to Surface 1<\/span>.\n

    Step 24<\/h2>\nTurn off all the layers except layer: Surface 1<\/span> and the model should appear as shown in the figure. (Figure Step 24)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"384\"]\"\" Figure Step 24[\/caption]\n

    Step 25<\/h2>\nSet the current visual style to Realistic. (Figure Step 25)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"266\"]\"\" Figure Step 25[\/caption]\n

    Step 26<\/h2>\nSave and close the drawing.\n
    \n\nAUTHOR'S COMMENTS: <\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model.\n\nThe advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.\n\n<\/div>\n
    \n

    AutoCAD Command: REVSURF<\/p>\n\n<\/header>\n

    \n\nThe REVSURF command is used to create a surface of revolution by revolving an existing profile around an axis.\n\nShortcut: none\n\nSURFTAB1 = YES\n\nSURFTAB2 = YES\n\n[caption id=\"attachment_567\" align=\"aligncenter\" width=\"508\"]\"\" Draw Pull-down[\/caption]\n\n[caption id=\"attachment_567\" align=\"aligncenter\" width=\"245\"]\"\" Mesh Ribbon[\/caption]\n\n<\/div>\n<\/div>\n

    WORK ALONG: Inserting Revolved Surfaces<\/h1>\n

    Step 1<\/h2>\nUsing the NEW command, start a new drawing using template: 3D Layout English<\/span>.\n

    Step 2<\/h2>\nSave and name the drawing: AutoCAD 3D Workalong 13-2<\/span>. (Figure Step 2)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"500\"]\"\" Figure Step 2
    Dimensioned Multiview Drawing[\/caption]\n

    Step 3<\/h2>\nSet the current layer to: Pline and the current visual style to 2D Wireframe.\n

    Step 4<\/h2>\nChange the current view to SE Isometric and the current UCS to Right.\n

    Step 5<\/h2>\nUsing the multiview drawing as a reference, draw the right side cross section of the solid part of the object. (Figure Step 5)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"144\"]\"\" Figure Step 5[\/caption]\n\n
    AUTHOR'S COMMENTS:<\/strong> You will be revolving this cross section 360 degrees to create a surface as it revolves. Therefore, only one-half of the section view is drawn.<\/div>\n

    Step 6<\/h2>\nOn layer: Construction<\/span>, draw a line, of any length, from 0,0,0 along the X axis. Enable ortho mode to draw it faster. This is the centre of the model and will be used as the axis for the revolution. (Figure Step 6)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"152\"]\"\" Figure Step 6[\/caption]\n\n
    AUTHOR'S COMMENTS:<\/strong> To convert the model objects to a closed polyline, the drawing must be perfectly drawn with the endpoints joining exactly. If you have problems using the PEDIT command to create a closed polygon, correct the drawing or redraw the objects from scratch.<\/div>\n

    Step 7<\/h2>\nUsing the PEDIT command, as shown below, convert the lines of the model to a closed polyline.\n\nCommand: PE<\/strong>\n\nSelect polyline or [Multiple]:\n\n(Select one line of the model.)<\/em><\/span>\n\nObject selected is not a polyline\n\nDo you want to turn it into one? <Y>\n\n(Press Enter to accept the default.)<\/em><\/span>\n\nEnter an option [Close\/Join\/Width\/Edit vertex\/Fit\/Spline\/Decurve\/Ltype gen\/Undo]: J<\/strong>\n\n(J for Join.)<\/em><\/span>\n\nSelect objects: ALL <\/strong>\n\n13 found\n\nSelect objects:\n\n11 segments added to polyline\n\nEnter an option [Open\/Join\/Width\/Edit vertex\/Fit\/Spline\/Decurve\/Ltype gen\/Undo]:\n\nCommand:\n

    Step 8<\/h2>\nTo ensure that you have successfully created a closed polyline, open the Properties window and select the polyline. The object type should read Polyline, all the objects should show as part of the polyline and the Closed property should indicate Yes. (Figure Step 8)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"409\"]\"\" Figure Step 8[\/caption]\n

    Step 9<\/h2>\nSet the system variable SURFTAB1 to 64 and SURFTAB2 to 24 as shown below.\n\nCommand: SURFTAB1<\/strong>\n\nEnter new value for SURFTAB1 <6>: 64<\/strong>\n\nCommand: SURFTAB2<\/strong>\n\nEnter new value for SURFTAB2 <6>: 24<\/strong>\n\nCommand:\n

    Step 10<\/h2>\nChange the current layer to layer: Surface 1 and enter the REVSURF command as shown below. After you complete the command, your model should appear as shown in the figure. (Figure Step 10)\n\nCommand: REVSURF<\/strong>\n\nCurrent wire frame density: SURFTAB1=64 SURFTAB2=24\n\nSelect object to revolve\n\n(Select the closed polyline.)<\/em><\/span>\n\nSelect object that defines the axis of revolution:\n\n(Select the axis line.)<\/em><\/span>\n\nSpecify start angle <0>:\n\n(Accept the default of 0.)<\/em><\/span>\n\nSpecify included angle (+=ccw, -=cw) <360>:\n\n(Accept the default of 360.)<\/em><\/span>\n\nCommand:\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"248\"]\"\" Figure Step 10[\/caption]\n

    Step 11<\/h2>\nTurn layers: Construction<\/span> and Pline off and set the current visual style to Realistic.\n

    Step 12<\/h2>\nUsing the 3DFORBIT command, orbit the model and look at all sides. (Figure 12A and 12B)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"197\"]\"\" Figure Step 12A
    SE Isometric View[\/caption]\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"188\"]\"\" Figure Step 12B
    SE Isometric View[\/caption]\n

    Step 13<\/h2>\nSave and close the drawing.\n
    \n

    AutoCAD Command: TABSURF<\/p>\n\n<\/header>\n

    \n\nThe TABSURF command is used to create a surface mesh moving a profile along a path. Shortcut: none\n\nSURFTAB1 = YES\n\nSURFTAB2 = No Effect\n\n[caption id=\"attachment_576\" align=\"aligncenter\" width=\"483\"]\"\" Draw Pull-down[\/caption]\n\n[caption id=\"attachment_576\" align=\"aligncenter\" width=\"307\"]\"\" Mesh Ribbon[\/caption]\n\n<\/div>\n<\/div>\n

    WORK ALONG: Inserting Tabulated Surfaces<\/h1>\n

    Step 1<\/h2>\nUsing the NEW command, start a new drawing using template: 3D Layout English<\/span>.\n

    Step 2<\/h2>\nSave and name the drawing: AutoCAD 3D Workalong 13-3<\/span>.\n

    Step 3<\/h2>\nSet the current visual style to 2D Wireframe, the current view to SE Isometric, and the current UCS to World.\n

    Step 4<\/h2>\nSet layer: Construction<\/span> as the current layer. Draw the model shown in the dimensioned model. These are the construction lines and arcs to be used to construct the model. When complete, your model will appear as shown in the figure. The length of the lines that appear dashed in the dimensioned model are not important since they are axis lines only. They are always drawn in the Z direction of the current UCS. They can be drawn any length as continuous linetype. (Figure Step 4A, 4B, and 4C)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"500\"]\"\" Figure Step 4A Dimensioned Model SE Isometric View[\/caption]\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"293\"]\"\" Figure Step 4B
    SE Isometric View[\/caption]\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"296\"]\"\" Figure Step 4C
    Orbited View[\/caption]\n\n
    AUTHOR'S COMMENTS:<\/strong> You will have to change the current UCS as you draw the construction lines to ensure that you are drawing on the correct plane.<\/div>\n

    Step 5<\/h2>\nSet the current UCS to Front and then draw a model of the object shown in the dimensioned drawing. The drawing should appear as shown in the figure. Draw the model anywhere in model space. Its location is not important. (Figure Step 5A and 5B)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"253\"]\"\" Figure Step 5A[\/caption]\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"134\"]\"\" Figure Step 5B[\/caption]\n

    Step 6<\/h2>\nChange the lines and arcs into two closed polylines using the PEDIT command. Check them using the Properties window. (Figure Step 6)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"435\"]\"\" Figure Step 6[\/caption]\n

    Step 7<\/h2>\nOn layer: Construction<\/span>, draw in two construction lines from midpoint of the lines to find the exact centre of the object. (Figure Step 7)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"135\"]\"\" Figure Step 7[\/caption]\n

    Step 8<\/h2>\nMake three additional copies of the model and rotate them to lay on different UCS planes. Their location in 3D space is not important. (Figure Step 8)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"435\"]\"\" Figure Step 8[\/caption]\n

    Step 9<\/h2>\nYour drawing should appear similar to the figure. (Figure Step 9)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"443\"]\"\" Figure Step 9[\/caption]\n

    Step 10<\/h2>\nCopy the objects onto the construction lines. Ensure that the midpoint of the object (the intersections of the construction lines) aligns to the endpoints of the lines and arcs. (Figure Step 10)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"500\"]\"\" Figure Step 10[\/caption]\n

    Step 11<\/h2>\nWith the UCS located on the Front, SURFTAB1 set to 48 and layer: Surface 1 as the current layer, enter the TABSURF command, as shown below, to create the surface for the inside of the tube. (Figure Step 11)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"377\"]\"\" Figure Step 11[\/caption]\n\nCommand: TABSURF<\/strong>\n\nCurrent wire frame density: SURFTAB1=48\n\nSelect object for path curve:\n\n(Select the inside polyline.)<\/em><\/span>\n\nSelect object for direction vector:\n\n(Select the construction axis line. Ensure you select it closer to the end where the object your are tabulating is located.)<\/em><\/span>\n\nCommand:\n

    Step 12<\/h2>\nSet the current visual style to Realistic. (Figure Step 12)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"356\"]\"\" Figure Step 12[\/caption]\n

    Step 13<\/h2>\nUsing the TABSURF command, create the surface for the outside of the tube. (Figure Step 13)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"248\"]\"\" Figure Step 13[\/caption]\n

    Step 14<\/h2>\nEnter the REVSURF command, as shown below, to construct the inside of the tube around the first corner. First change the layer of the straight tube surfaces constructed in Steps 11 to 13 to layer: Surface Off. (Figure Step 14)\n\nCommand: REVSURF<\/strong>\n\nCurrent wire frame density: SURFTAB1=48 SURFTAB2=6\n\nSelect object to revolve:\n\n(Select the inside polyline.)<\/em><\/span>\n\nSelect object that defines the axis of revolution\n\n(Select the axis line.)<\/em><\/span>\n\nSpecify start angle <0>:\n\n(Accept the default.)<\/em><\/span>\n\nSpecify included angle (+=ccw, -=cw) <360>: -90<\/strong>\n\nCommand:\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"311\"]\"\" Figure Step 14[\/caption]\n

    Step 15<\/h2>\nUsing what was just taught, construct the outside of the tube and change the layers of the surfaces until the model appear as shown in the figure. (Figure Step 15)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"482\"]\"\" Figure Step 15[\/caption]\n

    Step 16<\/h2>\nUsing what was just taught, complete the model. (Figure Step 16)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"416\"]\"\" Figure Step 16[\/caption]\n

    Step 17<\/h2>\nTurn off layers: Model<\/span> and Construction<\/span> and your completed model will appear as shown in the figure. (Figure Step 17)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"328\"]\"\" Figure Step 17[\/caption]\n

    Step 18<\/h2>\nSave and close the drawing.\n
    \n\nAUTHOR'S COMMENTS: <\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model. The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.\n\n<\/div>\n
    USER TIP:<\/strong> Although any surfacing command can be used to create the surfaces, the RULESURF command is the easiest and fastest to use for most surfaces. To shorten the modeling time, use it whenever possible.<\/div>\n

    Key Principles<\/h1>\n
    \n

    Key Principles in Module 13<\/p>\n\n<\/header>\n

    \n
      \n \t
    1. Geometrically defined surface meshes use existing geometry that must be created before the surfaces. In almost all cases, you will use the wireframe of the model as the existing geometry.<\/li>\n \t
    2. Although any surfacing command can be used to create a surface, the RULESURF command is the easiest and fastest to use for most surfaces.<\/li>\n \t
    3. When using the RULESURF command, ensure that you select the objects closest to matching If opposite ends are selected, the mesh will twist.<\/li>\n \t
    4. The mesh density represented by the lines, circles or arcs that make the rows and columns of the surface mesh are controlled with the system variables SURFTAB1 and SURFTAB2.<\/li>\n<\/ol>\n<\/div>\n<\/div>\n

      Lab Exercise 13-1<\/h1>\nTime allowed: 45 minutes.\n\n\n\n\n
      Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
      AutoCAD 3D Lab 13-1<\/td>\n3D English<\/td>\nInches<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

      Step 1<\/h2>\nDraw a wireframe of the object shown in the figure. (Figure Step 1)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"500\"]\"\" Figure Step 1
      Dimensioned Multiview Drawing[\/caption]\n

      Step 2<\/h2>\nPick appropriate mesh densities and on layer: Surface 2<\/span>, create surface meshes on all surfaces including back and bottom. (Figure Step 2)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"332\"]\"\" Figure Step 2
      Completed Model SE Isometric View[\/caption]\n

      Step 3<\/h2>\nFreeze layers: Construction<\/span> and Model<\/span>.\n

      Step 4<\/h2>\nSet the current visual style to Realistic. Use the 3DORBIT command to check that the model is surfaced on all sides.\n

      Step 5<\/h2>\nSet the Insertion Units, change the current UCS to World<\/span> and check the model with the key.\n

      Step 6<\/h2>\nSave and close the drawing.\n

      Lab Exercise 13-2<\/h1>\nTime allowed: 45 minutes.\n\n\n\n\n
      Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
      AutoCAD 3D Lab 13-2<\/td>\nN\/A<\/td>\nInches<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

      Step 1<\/h2>\nOpen the drawing: AutoCAD 3D Lab 04-1<\/span>.\n

      Step 2<\/h2>\nSave the drawing with the name: AutoCAD 3D Lab 13-2<\/span>.\n

      Step 3<\/h2>\nOn layer: Surface 5<\/span>, create surface meshes on all surfaces including back and bottom. (Figure Step 3)\n

      Step 4<\/h2>\nFreeze layers: Construction<\/span> and Model<\/span>.\n

      Step 5<\/h2>\nSet the current visual style to Realistic. Use the 3DFORBIT command to check that the model is surfaced on all sides.\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"300\"]\"\" Figure Step 3 Completed Model SE Isometric View[\/caption]\n

      Step 6<\/h2>\nSave and close the drawing.\n
      \n\nAUTHOR'S COMMENTS: <\/strong><\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model.The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.\n\n<\/div>\n

      Lab Exercise 13-3<\/h1>\nTime allowed: 45 minutes.\n\n\n\n\n
      Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
      AutoCAD 3D Lab 13-3<\/td>\nN\/A<\/td>\nInches<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

      Step 1<\/h2>\nOpen the drawing: AutoCAD 3D Lab 08-1.\n

      Step 2<\/h2>\nSave the drawing with the name: AutoCAD 3D Lab 13-3.\n

      Step 3<\/h2>\nOn layer: Surface 1, create surfaces on each side including back and bottom. (Figure Step 3)\n

      Step 4<\/h2>\nFreeze layers: Construction<\/span> and Model<\/span>.\n

      Step 5<\/h2>\nSet the current visual style to Realistic. Use the 3DFORBIT command to check that the model is surfaced on all sides.\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"277\"]\"\" Figure Step 3 Completed Model SE Isometric View[\/caption]\n

      Step 6<\/h2>\nSave and close the drawing.\n
      \n\nAUTHOR'S COMMENTS: <\/strong><\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model.The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.\n\n<\/div>\n

      Lab Exercise 13-4<\/h1>\nTime allowed: 45 minutes.\n\n\n\n\n
      Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
      AutoCAD 3D Lab 13-4<\/td>\n3D Layout Metric<\/td>\nMillimeters<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

      Step 1<\/h2>\nOn layer: Pline<\/span>, draw the cross section of the top half of the model on the right side UCS. (Figure Step 1A and 1B)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"500\"]\"\"
      Figure Step 1A
      Dimensioned Multiview Drawing[\/caption]\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"106\"]\"\" Figure Step 1B View Of a Cross Section to Revolve[\/caption]\n

      Step 2<\/h2>\nCreate a surface revolution on layer: Surface 1.<\/span> (Figure Step 2)\n\n[caption id=\"attachment_600\" align=\"aligncenter\" width=\"300\"]\"\" Figure Step 2 Complete Model SE Isometric View[\/caption]\n

      Step 3<\/h2>\nFreeze layers: Pline<\/span> and Construction<\/span>.\n

      Step 4<\/h2>\nSet the current visual style to Realistic. Use the 3DORBIT command to check that the model is surfaced on all sides.\n

      Step 5<\/h2>\nSet the Insertion Units, change the current UCS to World and check the model with the key.\n

      Step 6<\/h2>\nSave and close the drawing.\n
      \n\nAUTHOR'S COMMENTS: <\/strong><\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model. The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.\n\n<\/div>","rendered":"
      \n
      \n

      Learning Outcomes<\/p>\n<\/header>\n

      \n

      When you have completed this module, you will be able to:<\/p>\n

        \n
      1. Describe geometry defined meshes including rule surfaces, revolved surfaces, and tabulated surfaces.<\/li>\n
      2. Apply the RULESURF, REVSURF, and TABSURF commands to apply mesh surfaces to 3D models.<\/li>\n<\/ol>\n<\/div>\n<\/div>\n

        Geometry Defined Surface Meshes<\/h1>\n

        Geometrically defined surface meshes <\/em><\/span>use existing geometry that must be created before the surfaces. In almost all cases, the wireframe of the model is used as the existing geometry. There are four geometrically defined surface meshes that can be created in AutoCAD. They are the ruled surface, revolved surface, tabulated surface, and edge surface. The commands to create these meshes are RULESURF, REVSURF, TABSURF, and EDGESURF. The EDGESURF command is taught in Module 15.<\/p>\n

        To create a geometry defined surface mesh, start with the wireframe geometry and ensure that it is on its own layer. Surface the wireframe model on all sides, making sure that all exposed sides have a surface covering them. Think of the model as an object that must be made water tight.<\/p>\n

        Even the inside of a hole going through the model must have a surface applied on it. Place the surface meshes on their own layer. When the surfaced model is complete, freeze the layer containing the wireframe or the geometry leaving only the layer with the surface mesh displayed.<\/p>\n

        Ruled Surface<\/h2>\n

        A ruled surface<\/em><\/span>, inserted with the RULESURF command, is the most commonly used method to surface a model. To place a ruled surface, simply select two lines, a line and an arc, two arcs, or two circles to place the surface between. See Figure 13-1.<\/p>\n

        \"\"
        Figure 13-1
        Ruled Surface<\/figcaption><\/figure>\n

        Revolved Surface<\/h2>\n

        A revolved surface<\/em><\/span>, inserted with the REVSURF command, is a surface created by revolving a profile around an axis. The profile can be a line, arc, circle, or an open or closed 2D polyline or 3D polyline. See Figure 13-2. The axis must be a line or an open 2D or 3D polyline. If a polyline is used as the axis, the REVSURF command will simply use a straight line between the start point and end point of the polyline.<\/p>\n

        \"\"
        Figure 13-2
        Revolved Surface<\/figcaption><\/figure>\n

        Tabulated Surface<\/h2>\n

        A tabulated surface<\/span>, <\/em>inserted with the TABSURF command, is a surface created by projecting a profile along a path. The profile defines the surface of the mesh as it follows the path. See Figure 13-3. The profile can be a line, arc, circle, ellipse, or an open or closed 2D or 3D polyline. The path can be a line or a polyline. If a polyline is used as the axis, the TABSURF command will simply use a straight line between the start point and end point of the polyline. The surface is drawn starting at the point on the profile closest to the point selected in the command.<\/p>\n

        \"\"
        Figure 13-3
        Tabulated Surface<\/figcaption><\/figure>\n

        Setting the Mesh Density<\/h2>\n

        The mesh density<\/span> <\/em>represented by the lines, circles, or arcs that make the rows and columns of the surface mesh are controlled with the system variables SURFTAB1 and SURFTAB2. On flat surfaces, the density of the mesh is not that important but with curved or irregular shaped surfaces, the density is very important since the higher the setting, the more segments are used when creating circles and arcs. If the mesh is not dense enough, small gaps will be left where a curved surface meets a flat surface. See Figure 13-4.<\/p>\n

        \"\"
        Figure 13-4
        SURFTAB Settings<\/figcaption><\/figure>\n
        \n
        \n

        AutoCAD Command: RULESURF<\/p>\n<\/header>\n

        \n

        The RULESURF command is used to create a rule surface between two existing edges.<\/p>\n

        Shortcut: none<\/p>\n

        SURFTAB1 = YES<\/p>\n

        SURFTAB2 = No Effect<\/p>\n

        \"\"
        Draw Pull-down<\/figcaption><\/figure>\n
        \"\"
        Mesh Ribbon<\/figcaption><\/figure>\n<\/div>\n<\/div>\n

        WORK ALONG: Inserting Ruled Surfaces<\/h1>\n

        Step 1<\/h2>\n

        Using the NEW command, start a new drawing using template: 3D Layout Metric<\/span>.<\/p>\n

        Step 2<\/h2>\n

        Save and name the drawing: AutoCAD 3D Workalong 13-1<\/span>.<\/p>\n

        Step 3<\/h2>\n

        Set the current layer to: Model<\/span> and the current visual style to 2D Wireframe.<\/p>\n

        Step 4<\/h2>\n

        Draw a wireframe model of the multiview drawing. (Figure Step 4A and 4B)<\/p>\n

        \"\"
        Figure Step 4A
        Wireframe Model<\/figcaption><\/figure>\n
        \"\"
        Figure Step 4B
        Dimensioned Multiview Drawing<\/figcaption><\/figure>\n

        Step 5<\/h2>\n

        Set the system variable SURFTAB1 to 24 as shown below: Command: SURFTAB1<\/strong><\/p>\n

        Enter new value for SURFTAB1 <8>: 24<\/strong><\/p>\n

        Command:<\/p>\n

        AUTHOR’S COMMENTS:<\/strong> Setting SURFTAB1 to 24 sets the mesh density to 24 for the ruled surfaced inserted.<\/div>\n

        Step 6<\/h2>\n

        On layer: Construction<\/span>, draw a line along the top edge of each side of the model. (Figure Step 6)<\/p>\n

        \"\"
        Figure Step 6<\/figcaption><\/figure>\n
        AUTHOR’S COMMENTS:<\/strong> On some models, construction lines must be drawn on the wireframe to make it easier to insert surfaces.<\/div>\n

        Step 7<\/h2>\n

        Set layer: Surface 1<\/span> as the current layer. Enter the RULESURF command, as shown below, to insert a ruled surface. (Figure Step 7A and 7B)<\/p>\n

        Command: RULESURF<\/strong><\/p>\n

        Current wire frame density: SURFTAB1=24<\/p>\n

        Select first defining curve: P1<\/strong><\/p>\n

        Select second defining curve: P2<\/strong><\/p>\n

        Command:<\/p>\n

        \"\"
        Figure Step 7A<\/figcaption><\/figure>\n
        \"\"
        Figure Step 7B<\/figcaption><\/figure>\n

        Step 8<\/h2>\n

        Repeat the RULESURF command and insert surfaces all around the edge of the model. (Figure Step 8)<\/p>\n

        \"\"
        Figure Step 8<\/figcaption><\/figure>\n

        Step 9<\/h2>\n

        Turn layer: Surface Off<\/span> off and lock layers: Model<\/span> and Construction<\/span>. Select all of the surfaces inserted in Steps 7 and 8 and change their layer to: Surface Off<\/span>. (Figure Step 9)<\/p>\n

        \"\"
        Figure Step 9<\/figcaption><\/figure>\n
        AUTHOR’S COMMENTS: <\/strong>I use a little trick in Step 9 to help you when surfacing the model. I temporarily change the layers of newly created surfaces to a layer that is turned off. That way, the surfaces do not display and get in the way while you are inserted additional surfaces on the model. When all of the surfaces are inserted to complete the model, turn layer Surface Off on and change the layer of all surfaces back to layer Surface 1. The reason I locked layers Model and Construction is to make is easier to select only the surfaces using windows when changing their layer property.<\/div>\n

        Step 10<\/h2>\n

        Using what was just taught, insert ruled surfaces around the top of the object and inside of the hole as shown in the figure. (Figure Step 10).<\/p>\n

        \"\"
        Figure Step 10<\/figcaption><\/figure>\n

        Step 11<\/h2>\n

        Change the layer of the surfaces inserted in Step 10 to layer: Surface Off<\/span>.<\/p>\n

        Step 12<\/h2>\n

        On layer: Construction<\/span>, draw the construction lines on the top surface as shown in the figure. Ensure to snap to the endpoints of the lines and arcs. (Figure Step 12)<\/p>\n

        \"\"
        Figure Step 12<\/figcaption><\/figure>\n
        MUST KNOW:<\/strong> When using the RULESURF command, ensure that you select the objects closest to matching ends. If opposite ends are selected, the mesh will twist as shown in the figure.\"\"<\/div>\n

        Step 13<\/h2>\n

        On layer: Surface 1<\/span>, use the RULESURF command to insert the surfaces as shown in the figure. Change the surfaces the layer: Surface off<\/span>. (Figure Step 13)<\/p>\n

        \"\"
        Figure Step 13<\/figcaption><\/figure>\n

        Step 14<\/h2>\n

        On layer: Surface 1<\/span>, use the RULESURF command to draw surfaces as shown in the figure. Change the layer of the surfaces to layer: Surface off<\/span>. (Figure Step 14)<\/p>\n

        \"\"
        Figure Step 14<\/figcaption><\/figure>\n

        Step 15<\/h2>\n

        On layer: Construction<\/span>, draw a 180 degree arc on the top half of the circle. Ensure that you snap to the quads of the circle. To do that, ensure to locate the UCS on the same plane as the circle. (Figure Step 15)<\/p>\n

        \"\"
        Figure Step 15<\/figcaption><\/figure>\n

        Step 16<\/h2>\n

        On layer: Surface 1<\/span>, insert a ruled surface between the arcs. (Figure Step 16)<\/p>\n

        \"\"
        Figure Step 16<\/figcaption><\/figure>\n
        AUTHOR’S COMMENTS:<\/strong> Ensure that you select the arc instead of the circle under it. Sometimes, this can be tricky.<\/div>\n

        Step 17<\/h2>\n

        Change the layer of the surface that you just drew to layer: Surface Off<\/span>.<\/p>\n

        Step 18<\/h2>\n

        Draw two construction lines and a construction arc on the bottom half of the circle. (Figure Step 18)<\/p>\n

        \"\"
        Figure Step 18<\/figcaption><\/figure>\n

        Step 19<\/h2>\n

        On layer: Surface 1<\/span>, insert a ruled surface. (Figure Step 19)<\/p>\n

        \"\"
        Figure Step 19<\/figcaption><\/figure>\n

        Step 20<\/h2>\n

        On layer: Surface 1<\/span>, insert the ruled surfaces as shown in the figure. (Figure Step 20)<\/p>\n

        \"\"
        Figure Step 20<\/figcaption><\/figure>\n

        Step 21<\/h2>\n

        Change the layer of the existing surfaces to layer: Surface 1<\/span> until your model matches the figure. (Figure Step 21)<\/p>\n

        \"\"
        Figure Step 21<\/figcaption><\/figure>\n

        Step 22<\/h2>\n

        Copy the surfaces from the front side of the model to back side. (Figure Step 22)<\/p>\n

        \"\"
        Figure Step 22<\/figcaption><\/figure>\n
        AUTHOR’S COMMENTS:<\/strong> To help you surface a model faster, you can copy surfaces from one side of a model to another, if they are identical.<\/div>\n

        Step 23<\/h2>\n

        Using what was just taught, complete surfacing the model. Ensure to surface the bottom of the model. When complete, change all the surfaces from layers: Surface off<\/span> to Surface 1<\/span>.<\/p>\n

        Step 24<\/h2>\n

        Turn off all the layers except layer: Surface 1<\/span> and the model should appear as shown in the figure. (Figure Step 24)<\/p>\n

        \"\"
        Figure Step 24<\/figcaption><\/figure>\n

        Step 25<\/h2>\n

        Set the current visual style to Realistic. (Figure Step 25)<\/p>\n

        \"\"
        Figure Step 25<\/figcaption><\/figure>\n

        Step 26<\/h2>\n

        Save and close the drawing.<\/p>\n

        \n

        AUTHOR’S COMMENTS: <\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model.<\/p>\n

        The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.<\/p>\n<\/div>\n

        \n
        \n

        AutoCAD Command: REVSURF<\/p>\n<\/header>\n

        \n

        The REVSURF command is used to create a surface of revolution by revolving an existing profile around an axis.<\/p>\n

        Shortcut: none<\/p>\n

        SURFTAB1 = YES<\/p>\n

        SURFTAB2 = YES<\/p>\n

        \"\"
        Draw Pull-down<\/figcaption><\/figure>\n
        \"\"
        Mesh Ribbon<\/figcaption><\/figure>\n<\/div>\n<\/div>\n

        WORK ALONG: Inserting Revolved Surfaces<\/h1>\n

        Step 1<\/h2>\n

        Using the NEW command, start a new drawing using template: 3D Layout English<\/span>.<\/p>\n

        Step 2<\/h2>\n

        Save and name the drawing: AutoCAD 3D Workalong 13-2<\/span>. (Figure Step 2)<\/p>\n

        \"\"
        Figure Step 2
        Dimensioned Multiview Drawing<\/figcaption><\/figure>\n

        Step 3<\/h2>\n

        Set the current layer to: Pline and the current visual style to 2D Wireframe.<\/p>\n

        Step 4<\/h2>\n

        Change the current view to SE Isometric and the current UCS to Right.<\/p>\n

        Step 5<\/h2>\n

        Using the multiview drawing as a reference, draw the right side cross section of the solid part of the object. (Figure Step 5)<\/p>\n

        \"\"
        Figure Step 5<\/figcaption><\/figure>\n
        AUTHOR’S COMMENTS:<\/strong> You will be revolving this cross section 360 degrees to create a surface as it revolves. Therefore, only one-half of the section view is drawn.<\/div>\n

        Step 6<\/h2>\n

        On layer: Construction<\/span>, draw a line, of any length, from 0,0,0 along the X axis. Enable ortho mode to draw it faster. This is the centre of the model and will be used as the axis for the revolution. (Figure Step 6)<\/p>\n

        \"\"
        Figure Step 6<\/figcaption><\/figure>\n
        AUTHOR’S COMMENTS:<\/strong> To convert the model objects to a closed polyline, the drawing must be perfectly drawn with the endpoints joining exactly. If you have problems using the PEDIT command to create a closed polygon, correct the drawing or redraw the objects from scratch.<\/div>\n

        Step 7<\/h2>\n

        Using the PEDIT command, as shown below, convert the lines of the model to a closed polyline.<\/p>\n

        Command: PE<\/strong><\/p>\n

        Select polyline or [Multiple]:<\/p>\n

        (Select one line of the model.)<\/em><\/span><\/p>\n

        Object selected is not a polyline<\/p>\n

        Do you want to turn it into one? <Y><\/p>\n

        (Press Enter to accept the default.)<\/em><\/span><\/p>\n

        Enter an option [Close\/Join\/Width\/Edit vertex\/Fit\/Spline\/Decurve\/Ltype gen\/Undo]: J<\/strong><\/p>\n

        (J for Join.)<\/em><\/span><\/p>\n

        Select objects: ALL <\/strong><\/p>\n

        13 found<\/p>\n

        Select objects:<\/p>\n

        11 segments added to polyline<\/p>\n

        Enter an option [Open\/Join\/Width\/Edit vertex\/Fit\/Spline\/Decurve\/Ltype gen\/Undo]:<\/p>\n

        Command:<\/p>\n

        Step 8<\/h2>\n

        To ensure that you have successfully created a closed polyline, open the Properties window and select the polyline. The object type should read Polyline, all the objects should show as part of the polyline and the Closed property should indicate Yes. (Figure Step 8)<\/p>\n

        \"\"
        Figure Step 8<\/figcaption><\/figure>\n

        Step 9<\/h2>\n

        Set the system variable SURFTAB1 to 64 and SURFTAB2 to 24 as shown below.<\/p>\n

        Command: SURFTAB1<\/strong><\/p>\n

        Enter new value for SURFTAB1 <6>: 64<\/strong><\/p>\n

        Command: SURFTAB2<\/strong><\/p>\n

        Enter new value for SURFTAB2 <6>: 24<\/strong><\/p>\n

        Command:<\/p>\n

        Step 10<\/h2>\n

        Change the current layer to layer: Surface 1 and enter the REVSURF command as shown below. After you complete the command, your model should appear as shown in the figure. (Figure Step 10)<\/p>\n

        Command: REVSURF<\/strong><\/p>\n

        Current wire frame density: SURFTAB1=64 SURFTAB2=24<\/p>\n

        Select object to revolve<\/p>\n

        (Select the closed polyline.)<\/em><\/span><\/p>\n

        Select object that defines the axis of revolution:<\/p>\n

        (Select the axis line.)<\/em><\/span><\/p>\n

        Specify start angle <0>:<\/p>\n

        (Accept the default of 0.)<\/em><\/span><\/p>\n

        Specify included angle (+=ccw, -=cw) <360>:<\/p>\n

        (Accept the default of 360.)<\/em><\/span><\/p>\n

        Command:<\/p>\n

        \"\"
        Figure Step 10<\/figcaption><\/figure>\n

        Step 11<\/h2>\n

        Turn layers: Construction<\/span> and Pline off and set the current visual style to Realistic.<\/p>\n

        Step 12<\/h2>\n

        Using the 3DFORBIT command, orbit the model and look at all sides. (Figure 12A and 12B)<\/p>\n

        \"\"
        Figure Step 12A
        SE Isometric View<\/figcaption><\/figure>\n
        \"\"
        Figure Step 12B
        SE Isometric View<\/figcaption><\/figure>\n

        Step 13<\/h2>\n

        Save and close the drawing.<\/p>\n

        \n
        \n

        AutoCAD Command: TABSURF<\/p>\n<\/header>\n

        \n

        The TABSURF command is used to create a surface mesh moving a profile along a path. Shortcut: none<\/p>\n

        SURFTAB1 = YES<\/p>\n

        SURFTAB2 = No Effect<\/p>\n

        \"\"
        Draw Pull-down<\/figcaption><\/figure>\n
        \"\"
        Mesh Ribbon<\/figcaption><\/figure>\n<\/div>\n<\/div>\n

        WORK ALONG: Inserting Tabulated Surfaces<\/h1>\n

        Step 1<\/h2>\n

        Using the NEW command, start a new drawing using template: 3D Layout English<\/span>.<\/p>\n

        Step 2<\/h2>\n

        Save and name the drawing: AutoCAD 3D Workalong 13-3<\/span>.<\/p>\n

        Step 3<\/h2>\n

        Set the current visual style to 2D Wireframe, the current view to SE Isometric, and the current UCS to World.<\/p>\n

        Step 4<\/h2>\n

        Set layer: Construction<\/span> as the current layer. Draw the model shown in the dimensioned model. These are the construction lines and arcs to be used to construct the model. When complete, your model will appear as shown in the figure. The length of the lines that appear dashed in the dimensioned model are not important since they are axis lines only. They are always drawn in the Z direction of the current UCS. They can be drawn any length as continuous linetype. (Figure Step 4A, 4B, and 4C)<\/p>\n

        \"\"
        Figure Step 4A Dimensioned Model SE Isometric View<\/figcaption><\/figure>\n
        \"\"
        Figure Step 4B
        SE Isometric View<\/figcaption><\/figure>\n
        \"\"
        Figure Step 4C
        Orbited View<\/figcaption><\/figure>\n
        AUTHOR’S COMMENTS:<\/strong> You will have to change the current UCS as you draw the construction lines to ensure that you are drawing on the correct plane.<\/div>\n

        Step 5<\/h2>\n

        Set the current UCS to Front and then draw a model of the object shown in the dimensioned drawing. The drawing should appear as shown in the figure. Draw the model anywhere in model space. Its location is not important. (Figure Step 5A and 5B)<\/p>\n

        \"\"
        Figure Step 5A<\/figcaption><\/figure>\n
        \"\"
        Figure Step 5B<\/figcaption><\/figure>\n

        Step 6<\/h2>\n

        Change the lines and arcs into two closed polylines using the PEDIT command. Check them using the Properties window. (Figure Step 6)<\/p>\n

        \"\"
        Figure Step 6<\/figcaption><\/figure>\n

        Step 7<\/h2>\n

        On layer: Construction<\/span>, draw in two construction lines from midpoint of the lines to find the exact centre of the object. (Figure Step 7)<\/p>\n

        \"\"
        Figure Step 7<\/figcaption><\/figure>\n

        Step 8<\/h2>\n

        Make three additional copies of the model and rotate them to lay on different UCS planes. Their location in 3D space is not important. (Figure Step 8)<\/p>\n

        \"\"
        Figure Step 8<\/figcaption><\/figure>\n

        Step 9<\/h2>\n

        Your drawing should appear similar to the figure. (Figure Step 9)<\/p>\n

        \"\"
        Figure Step 9<\/figcaption><\/figure>\n

        Step 10<\/h2>\n

        Copy the objects onto the construction lines. Ensure that the midpoint of the object (the intersections of the construction lines) aligns to the endpoints of the lines and arcs. (Figure Step 10)<\/p>\n

        \"\"
        Figure Step 10<\/figcaption><\/figure>\n

        Step 11<\/h2>\n

        With the UCS located on the Front, SURFTAB1 set to 48 and layer: Surface 1 as the current layer, enter the TABSURF command, as shown below, to create the surface for the inside of the tube. (Figure Step 11)<\/p>\n

        \"\"
        Figure Step 11<\/figcaption><\/figure>\n

        Command: TABSURF<\/strong><\/p>\n

        Current wire frame density: SURFTAB1=48<\/p>\n

        Select object for path curve:<\/p>\n

        (Select the inside polyline.)<\/em><\/span><\/p>\n

        Select object for direction vector:<\/p>\n

        (Select the construction axis line. Ensure you select it closer to the end where the object your are tabulating is located.)<\/em><\/span><\/p>\n

        Command:<\/p>\n

        Step 12<\/h2>\n

        Set the current visual style to Realistic. (Figure Step 12)<\/p>\n

        \"\"
        Figure Step 12<\/figcaption><\/figure>\n

        Step 13<\/h2>\n

        Using the TABSURF command, create the surface for the outside of the tube. (Figure Step 13)<\/p>\n

        \"\"
        Figure Step 13<\/figcaption><\/figure>\n

        Step 14<\/h2>\n

        Enter the REVSURF command, as shown below, to construct the inside of the tube around the first corner. First change the layer of the straight tube surfaces constructed in Steps 11 to 13 to layer: Surface Off. (Figure Step 14)<\/p>\n

        Command: REVSURF<\/strong><\/p>\n

        Current wire frame density: SURFTAB1=48 SURFTAB2=6<\/p>\n

        Select object to revolve:<\/p>\n

        (Select the inside polyline.)<\/em><\/span><\/p>\n

        Select object that defines the axis of revolution<\/p>\n

        (Select the axis line.)<\/em><\/span><\/p>\n

        Specify start angle <0>:<\/p>\n

        (Accept the default.)<\/em><\/span><\/p>\n

        Specify included angle (+=ccw, -=cw) <360>: -90<\/strong><\/p>\n

        Command:<\/p>\n

        \"\"
        Figure Step 14<\/figcaption><\/figure>\n

        Step 15<\/h2>\n

        Using what was just taught, construct the outside of the tube and change the layers of the surfaces until the model appear as shown in the figure. (Figure Step 15)<\/p>\n

        \"\"
        Figure Step 15<\/figcaption><\/figure>\n

        Step 16<\/h2>\n

        Using what was just taught, complete the model. (Figure Step 16)<\/p>\n

        \"\"
        Figure Step 16<\/figcaption><\/figure>\n

        Step 17<\/h2>\n

        Turn off layers: Model<\/span> and Construction<\/span> and your completed model will appear as shown in the figure. (Figure Step 17)<\/p>\n

        \"\"
        Figure Step 17<\/figcaption><\/figure>\n

        Step 18<\/h2>\n

        Save and close the drawing.<\/p>\n

        \n

        AUTHOR’S COMMENTS: <\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model. The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.<\/p>\n<\/div>\n

        USER TIP:<\/strong> Although any surfacing command can be used to create the surfaces, the RULESURF command is the easiest and fastest to use for most surfaces. To shorten the modeling time, use it whenever possible.<\/div>\n

        Key Principles<\/h1>\n
        \n
        \n

        Key Principles in Module 13<\/p>\n<\/header>\n

        \n
          \n
        1. Geometrically defined surface meshes use existing geometry that must be created before the surfaces. In almost all cases, you will use the wireframe of the model as the existing geometry.<\/li>\n
        2. Although any surfacing command can be used to create a surface, the RULESURF command is the easiest and fastest to use for most surfaces.<\/li>\n
        3. When using the RULESURF command, ensure that you select the objects closest to matching If opposite ends are selected, the mesh will twist.<\/li>\n
        4. The mesh density represented by the lines, circles or arcs that make the rows and columns of the surface mesh are controlled with the system variables SURFTAB1 and SURFTAB2.<\/li>\n<\/ol>\n<\/div>\n<\/div>\n

          Lab Exercise 13-1<\/h1>\n

          Time allowed: 45 minutes.<\/p>\n\n\n\n\n
          Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
          AutoCAD 3D Lab 13-1<\/td>\n3D English<\/td>\nInches<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

          Step 1<\/h2>\n

          Draw a wireframe of the object shown in the figure. (Figure Step 1)<\/p>\n

          \"\"
          Figure Step 1
          Dimensioned Multiview Drawing<\/figcaption><\/figure>\n

          Step 2<\/h2>\n

          Pick appropriate mesh densities and on layer: Surface 2<\/span>, create surface meshes on all surfaces including back and bottom. (Figure Step 2)<\/p>\n

          \"\"
          Figure Step 2
          Completed Model SE Isometric View<\/figcaption><\/figure>\n

          Step 3<\/h2>\n

          Freeze layers: Construction<\/span> and Model<\/span>.<\/p>\n

          Step 4<\/h2>\n

          Set the current visual style to Realistic. Use the 3DORBIT command to check that the model is surfaced on all sides.<\/p>\n

          Step 5<\/h2>\n

          Set the Insertion Units, change the current UCS to World<\/span> and check the model with the key.<\/p>\n

          Step 6<\/h2>\n

          Save and close the drawing.<\/p>\n

          Lab Exercise 13-2<\/h1>\n

          Time allowed: 45 minutes.<\/p>\n\n\n\n\n
          Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
          AutoCAD 3D Lab 13-2<\/td>\nN\/A<\/td>\nInches<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

          Step 1<\/h2>\n

          Open the drawing: AutoCAD 3D Lab 04-1<\/span>.<\/p>\n

          Step 2<\/h2>\n

          Save the drawing with the name: AutoCAD 3D Lab 13-2<\/span>.<\/p>\n

          Step 3<\/h2>\n

          On layer: Surface 5<\/span>, create surface meshes on all surfaces including back and bottom. (Figure Step 3)<\/p>\n

          Step 4<\/h2>\n

          Freeze layers: Construction<\/span> and Model<\/span>.<\/p>\n

          Step 5<\/h2>\n

          Set the current visual style to Realistic. Use the 3DFORBIT command to check that the model is surfaced on all sides.<\/p>\n

          \"\"
          Figure Step 3 Completed Model SE Isometric View<\/figcaption><\/figure>\n

          Step 6<\/h2>\n

          Save and close the drawing.<\/p>\n

          \n

          AUTHOR’S COMMENTS: <\/strong><\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model.The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.<\/p>\n<\/div>\n

          Lab Exercise 13-3<\/h1>\n

          Time allowed: 45 minutes.<\/p>\n\n\n\n\n
          Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
          AutoCAD 3D Lab 13-3<\/td>\nN\/A<\/td>\nInches<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

          Step 1<\/h2>\n

          Open the drawing: AutoCAD 3D Lab 08-1.<\/p>\n

          Step 2<\/h2>\n

          Save the drawing with the name: AutoCAD 3D Lab 13-3.<\/p>\n

          Step 3<\/h2>\n

          On layer: Surface 1, create surfaces on each side including back and bottom. (Figure Step 3)<\/p>\n

          Step 4<\/h2>\n

          Freeze layers: Construction<\/span> and Model<\/span>.<\/p>\n

          Step 5<\/h2>\n

          Set the current visual style to Realistic. Use the 3DFORBIT command to check that the model is surfaced on all sides.<\/p>\n

          \"\"
          Figure Step 3 Completed Model SE Isometric View<\/figcaption><\/figure>\n

          Step 6<\/h2>\n

          Save and close the drawing.<\/p>\n

          \n

          AUTHOR’S COMMENTS: <\/strong><\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model.The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.<\/p>\n<\/div>\n

          Lab Exercise 13-4<\/h1>\n

          Time allowed: 45 minutes.<\/p>\n\n\n\n\n
          Drawing Name<\/th>\nTemplate<\/th>\nUnits<\/th>\n<\/tr>\n
          AutoCAD 3D Lab 13-4<\/td>\n3D Layout Metric<\/td>\nMillimeters<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

          Step 1<\/h2>\n

          On layer: Pline<\/span>, draw the cross section of the top half of the model on the right side UCS. (Figure Step 1A and 1B)<\/p>\n

          \"\"
          Figure Step 1A
          Dimensioned Multiview Drawing<\/figcaption><\/figure>\n
          \"\"
          Figure Step 1B View Of a Cross Section to Revolve<\/figcaption><\/figure>\n

          Step 2<\/h2>\n

          Create a surface revolution on layer: Surface 1.<\/span> (Figure Step 2)<\/p>\n

          \"\"
          Figure Step 2 Complete Model SE Isometric View<\/figcaption><\/figure>\n

          Step 3<\/h2>\n

          Freeze layers: Pline<\/span> and Construction<\/span>.<\/p>\n

          Step 4<\/h2>\n

          Set the current visual style to Realistic. Use the 3DORBIT command to check that the model is surfaced on all sides.<\/p>\n

          Step 5<\/h2>\n

          Set the Insertion Units, change the current UCS to World and check the model with the key.<\/p>\n

          Step 6<\/h2>\n

          Save and close the drawing.<\/p>\n

          \n

          AUTHOR’S COMMENTS: <\/strong><\/strong>Do not be concerned if your shaded model does not match the figures in the module exactly. There are many visual style settings that can be set to change the look of the shaded model. For now, all you should be concerned about is being able to surface the model. The advanced features of customizing visual styles are taught in the AutoCAD 3D Advanced book.<\/p>\n<\/div>\n","protected":false},"author":90,"menu_order":2,"template":"","meta":{"pb_show_title":"on","pb_short_title":"","pb_subtitle":"","pb_authors":[],"pb_section_license":""},"chapter-type":[],"contributor":[],"license":[],"class_list":["post-601","chapter","type-chapter","status-publish","hentry"],"part":517,"_links":{"self":[{"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/pressbooks\/v2\/chapters\/601","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/pressbooks\/v2\/chapters"}],"about":[{"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/wp\/v2\/types\/chapter"}],"author":[{"embeddable":true,"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/wp\/v2\/users\/90"}],"version-history":[{"count":1,"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/pressbooks\/v2\/chapters\/601\/revisions"}],"predecessor-version":[{"id":602,"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/pressbooks\/v2\/chapters\/601\/revisions\/602"}],"part":[{"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/pressbooks\/v2\/parts\/517"}],"metadata":[{"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/pressbooks\/v2\/chapters\/601\/metadata\/"}],"wp:attachment":[{"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/wp\/v2\/media?parent=601"}],"wp:term":[{"taxonomy":"chapter-type","embeddable":true,"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/pressbooks\/v2\/chapter-type?post=601"},{"taxonomy":"contributor","embeddable":true,"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/wp\/v2\/contributor?post=601"},{"taxonomy":"license","embeddable":true,"href":"https:\/\/opentextbc.ca\/autocad3d\/wp-json\/wp\/v2\/license?post=601"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}